A. A. Yaroslavov

Three types of naturally occurring modified lipoproteins induce intracellular lipid accumulation due to lipoprotein aggregation.

Low density lipoprotein (LDL) from patients with coronary atherosclerosis and diabetes mellitus as well as in vitro desialylated LDL, glycosylated LDL, and lipoprotein (a) caused a twofold to fourfold rise in cholesteryl ester in cultured human blood monocytes and intimal smooth muscle cells isolated from normal aorta. Native LDL from healthy subjects failed to induce intracellular lipid accumulation. We have demonstrated by laser correlative photometry and gel filtration chromatography that in vivo and in vitro modified lipoproteins form aggregates under cell culture conditions. The degree of modified lipoprotein aggregation directly correlated with the ability of these lipoproteins to elevate the cholesteryl ester content of cultured cells. Modified lipoprotein aggregates isolated by gel filtration induced a threefold to fivefold elevation in cellular cholesteryl ester content. Aggregates of 125I-modified LDL were taken up and degraded fivefold to sevenfold more effectively as compared with nonaggregated lipoproteins. The uptake and degradation of 125I-labeled aggregates were strongly inhibited by unlabeled aggregates, latex beads, and cytochalasin B but not by native or acetylated LDL. These data indicate that uptake of lipoprotein aggregates occurred by phagocytosis. Obtained results suggest that modified lipoprotein aggregation may be the key condition for lipid accumulation.

Polyelectrolyte-coated liposomes: stabilization of the interfacial complexes.

Anionic liposomes, composed of egg lecithin (EL) or dipalmitoylphosphatidylcholine (DPPC) with 20 mol% of cardiolipin (CL(2-)), were mixed with cationic polymers, poly(4-vinylpyridine) fully quaternized with ethyl bromide (P2) or poly-L-lysine (PL). Polymer/liposome binding studies were carried out using electrophoretic mobility (EPM), fluorescence, and conductometry as the main analytical tools. Binding was also examined in the presence of added salt and polyacrylic acid (PAA). The following generalizations arose from the experiments: (a) Binding of P2 and PL to small EL/CL(2-) liposomes (60-80 nm in diameter) is electrostatic in nature and completely reversed by addition of salt or PAA. (b) Binding can be enhanced by hydrophobization of the polymer with cetyl groups. (c) Binding can also be enhanced by changing the phase state of the lipid bilayer from liquid to solid (i.e. going from EL to DPPC) or by increasing the size of the liposomes (i.e. going from 60-80 to 300 nm). By far the most promising systems, from the point of view of constructing polyelectrolyte multilayers on liposome cores without disruption of liposome integrity, involve small, liquid, anionic liposomes coated initially with polycations carrying pendant alkyl groups.

MODULATION OF INTERACTION OF POLYCATIONS WITH NEGATIVE UNILAMELLAR LIPID VESICLES

Interactions of small unilamellar negative vesicles composed of diphosphatidylglycerol (cardiolipin, CL2−), 20 mol%, and phosphatidylcholine (egg yolk lecithin, EL), 80 mol%, with various cationic polymers (CP) derived from poly(4-vinylpyridine) (PVP) were studied in water and water–salt solutions by means of photon correlation spectroscopy, microelectrophoresis, conductometry, and fluorescence techniques. The linear charge density and hydrophilic lipophilic balance of CPs were varied by quaternization of PVP with various amounts of different alkyl bromides (ethyl-(2), heptyl-(7), dodecyl-(12), cetyl-(16)). Substantial differences were observed in the behavior of exhaustingly N-ethylated PVP (CP2) and PVP N-ethylated to 50 mol% (CP2(50)) or 30 mol% (CP2(30)). All of them adsorb to the CL2−/EL vesicle membrane, neutralizing the surface negative charge and causing aggregation of the vesicles. However, CP2, a polycation with a maximum linear charge density, strongly enhances transfer of the negative lipid ions from the inner to outer bilayer leaflet, while CP2(50) and CP2(30) do not. Adsorbed CP2 does not disturb integrity of the vesicle membrane and can be completely removed from the surface of aggregated vesicles by adding a simple salt (NaCl) or a negative linear polyelectrolyte (polyacrylic acid (PAA) sodium salt). Such removal is followed by release of the original vesicles. In contrast to that, adsorbed CP2(50) or CP2(30) produce some leak through the lipid bilayer and cannot be completely desorbed either by increasing ionic strength or adding an excess of PAA. The probable reason of these differences is discussed. PVP partially N-alkylated with dodecyl or cetyl bromides (3 mol%) and then completely N-ethylated (CP2,12 and CP2,16), also having a maximum linear charge density, adsorbs to the negative vesicle surface as a result of both electrostatic binding and hydrophobic interaction. Bulky hydrocarbon pendant groups incorporate into the inner bilayer compartment. Similarly to CP2(50) and CP2(30), CP2,12 and CP2,16 cannot be removed from the surface either by adding the simple salt, or an excess of PAA. However, in contrast to CP2(50) and CP2(30), the polycations with the bulky hydrocarbon pendant groups do not cause any leak through the vesicle membrane. Finally, we have succeeded to prepare the ternary vesicles also composed of 20 mol% of CL2−, but partially replacing EL for polyoxyethylene 20 cetyl ether (Brij 58) (up to 30 mol%). The CL2−/EL/Brij vesicle carries a hydrophilic corona formed by polyoxyethylene chains exposed into water, while hydrophobic cetyl radicals are incorporated in the lipid bilayer. The CL2−/EL/Brij vesicles adsorb all studied CPs similar to the binary CL2−/EL vesicles. This means that polyoxyethylene corona is permeable for polycationic species restricting neither electrostatic binding nor incorporation of bulky hydrocarbon groups of CP2,16 into the membrane. However, the corona effectively stabilizes the CP-vesicle complexes against aggregation when the membrane surface is neutralized.

Reversibility of structural rearrangements in the negative vesicular membrane upon electrostatic adsorption/desorption of the polycation.

Interaction of small unilamellar vesicles (SUVs), composed of negative diphosphatidylglycerol (cardiolipin, CL(2-)) and neutral dipalmitoylphosphatidylcholine (DPPC), with poly(N-ethyl-4-vinylpyridinium bromide) (PEVP) was studied in water solution above and below the vesicular membrane melting point by means of differential scanning calorimetry, photon correlation spectroscopy, microelectrophoresis, conductometry, and fluorescence techniques. It has been found that CL(2-) species are homogeneously distributed within DPPC-CL(2-) SUV membrane leaflets and between them. Interaction of PEVP with DPPC-CL(2-) SUVs led to drastic structural rearrangements in the membrane if it was in the fluid state (liquid SUVs). Negative CL(2-) molecules migrated from the inner to the outer membrane leaflet and segregated in the vicinity of adsorbed PEVP chains. In addition, PEVP adsorption terminated completely the exchange of lipid molecules between the SUVs. At the same time, the integrity of liquid SUVs contacting PEVP remained unchanged. Since the interaction of PEVP with liquid SUVs was predominantly electrostatic in nature, the polycation could be completely removed from the vesicular membrane by addition of an excess of polyacrylic acid (PAA) polyanions forming a more stable electrostatic complex with PEVP. Removal of PEVP resulted in complete resumption of the original distribution of lipids in lateral and transmembrane directions as well as intervesicular lipid exchange. In contrast, PEVP interacting with DPPC-CL(2-) SUVs formed defects in the vesicular membrane if it was in the gel state (solid SUVs). Such interaction was contributed not only by electrostatic but most likely by hydrophobic interactions involving the defected membrane sites. PEVP kept contacting solid SUVs in the presence of an abundant amount of PAA. The established phenomena may be important for understanding the biological effects of polycations.

A polycation causes migration of negatively charged phospholipids from the inner to outer leaflet of the liposomal membrane

Aggregation of the negatively charged liposomes caused by the addition of the linear polycation, poly‐N‐ethyl‐4‐vinylpyridine bromide, was studied. At the point of maximal size and zero electrophoretic mobility of aggregates, the concentration of positive charges brought in by the adsorbed polycation was found to be equal to the total concentration of negative charges both on the outer and inner surface of the lipid bilayer. Since polycation saturation of the liposomal negative charges was found to occur without disruption of the membrane, it was concluded that the polycation induced migration of negatively charged phospholipid molecules from the inner to outer leaflet of the bilayer.

Liposome fusion rates depend upon the conformation of polycation catalysts.

Cryo-TEM and NaCl-leakage experiments demonstrated that the cationic polymer polylysine induces fusion of anionic liposomes but that the cationic polymer poly(N-ethyl-4-vinylpyridinium bromide) (PEVP) does not, although both polymers bind strongly to the liposomes. The difference was traced to the thickness of the coatings at constant charge coverage. Polylysine is believed to form planar β-sheets that are sufficiently thin to allow membrane fusion. In contrast, looping and disorganization among adsorbed PEVP molecules physically prevent fusion. A similar effect is likely to be applicable to important polycation-induced fusion of cell membranes.

Interaction of polyions with cell-mimetic species: Physico-chemical and biomedical aspects

The possibility of recognition and discrimination of relatively large charged supermolecular objects (latex species) by an oppositely charged polyion is demonstrated using a suspension of carboxylated and protein-modified latex particles interacting with the high molecular mass linear polycations including those conjugated with the specific protein (α-chymotrypsin). The polycations are strongly adsorbed on the latex surface. Nevertheless, they are able to migrate between the latex species via occasional interparticle contacts. Finally, the interchanging polycations carrying the specific protein are fixed on those latex particles which carry the complementary protein receptor (trypsin inhibitor from soybean). The presence of other proteins does not hinder such interaction. The resulting effect is considered to mimic a physico-chemical aspect of recognition of target cells by macromolecules combined with relatively small molecular vector. Interaction of the target cell membrane with a polycation was simulated using negatively charged liposomes. It was found that polycations adsorbed on the surface of liquid liposomes can cause a significant charge asymmetry in the lipid bilayer due to transmembrane migration of negatively charged lipids from the inner to outer leaflet. At the same time the liposomal membrane integrity can be retained and adsorbed polycations can be replaced from the membrane by recomplexation with polyanion species. The established phenomena may be important for understanding the biological effects of polycations. Negatively charged liquid liposomes were also used to mimic interaction of cells with DNA-polycation and DNA-cationic surfactant complexes used to enhance plasmid DNA translocation. It was found that the complex of DNA with the polycation carrying hydrophobic side groups interacted with the liposomes without dissociation and adsorbed on the liposome surface as a whole.

What happens to negatively charged lipid vesicles upon interacting with polycation species

Complexation of synthetic polycations with negative lipid vesicles as cell-mimetic species was studied. It was found that such interaction could be accompanied by lateral lipid segregation, highly accelerated transmembrane migration of lipid molecules (polycation-induced flip-flop), incorporation of adsorbed polycations into vesicular membrane as well as aggregation and disruption of vesicles. A polycation adsorbed on the surface of liquid vesicles due to electrostatic attraction could be completely removed from the membrane by increase in simple salt concentration or by recomplexation with polyanions. In contrast, adsorption of a polycation carrying pendant hydrophobic groups was irreversible apparently due to incorporation of these groups into the hydrophobic part of the vesicular membrane. The above mentioned phenomena were examined depending on the polycation structure, fraction of charged lipids in the membrane, vesicle phase state and ionic strength of solution.

Liposomes remain intact when complexed with polycationic brushes

Anionic liposomes adsorb onto the surface of spherical polymer particles bearing grafted linear cationic macromolecules. The size, shape, and encapsulation ability of the liposomes remain unchanged upon adsorption, thus providing immobilized self-organizing containers that have potential applications in the biomedical field.

Interaction of a cationic polymer with negatively charged proteoliposomes.

Proteoliposomes were prepared by making bilayer vesicles from neutral egg yolk lecithin and negatively charged alpha-chymotrypsin that had been previously stearoylated. Interaction of these proteoliposomes with a cationic polymer, poly-(N-ethyl-4-vinylpryidinium bromide) (PEVP) was examined. For comparison purposes, interaction of PEVP with egg lecithin vesicles containing an anionic phospholipid, cardiolipin, was also examined. Binding of PEVP to both types of vesicles was electrostatic in nature with the polymer manifesting a higher affinity to the cardiolipin relative to the enzyme. PEVP had no effect on the permeability of the bilayer membranes to sodium chloride. On the other hand, PEVP increased the transmembrane permeability of the nonionic anti-tumor drug, doxorubicin. The greater the negatively charged component in the membrane, the greater the PEVP effect. Polycation binding to the vesicles was accompanied by clustering of the stearoylated chymotrypsin (sCT) molecules within the membrane. This protein clustering is most likely responsible for the increase in the doxorubicin permeation. Enzymatic activity of the membrane-associated sCT remained unchanged upon PEVP binding. These findings seem relevant to the effects of polyelectrolytes on cellular membranes.